KR102495073B1 - Waterproof anti-corrosion system using diagonal engraved pattern - Google Patents

Abstract

The present invention relates to a waterproof anti-corrosion system using a diagonal engraved pattern constructed in an exposed or non-exposed manner. Main components of the present invention include a waterproof anti-corrosive sheet (20) formed by laminating a PVC sheet and reinforcing glass fibers. According to the present invention, since joint parts are overlapped in the vertical direction between compound layers of the waterproof anti-corrosive sheet to form an overlapping part, the watertightness and durability against external stress are highly improved. In addition to flexible absorption of wetting behavior, the present invention an effectively block the spread of leaks while smoothly distributing and moving wetting.

Description

Waterproof anti-corrosion system using diagonal engraved pattern}

The present invention relates to a waterproof anticorrosive system using an oblique intaglio pattern, and more specifically, since the joints are overlapped in the vertical direction between the compound layers of the waterproof anticorrosive sheet to form an overlap, watertightness and durability against external stress are highly improved, In particular, wetting behavior is flexibly absorbed by the oblique intaglio pattern formed on the bottom of the waterproof anticorrosive sheet, and the waterproof anticorrosion system using an oblique intaglio pattern that can effectively block the spread of leaks while smoothly distributing and moving the wetting.

In the case of constructing a rooftop in the form of a concrete slab, water leaked into the building by melting rainwater or snow occurs through numerous fine pores formed on the bottom surface of the rooftop slab. The bottom surface of the roof slab must be waterproofed.

At this time, the rooftop slab waterproofing construction is performed for the purpose of extending the life of the building by protecting the rooftop slab as well as blocking water leakage. Although waterproofing is known, this rooftop waterproofing construction method repeats expansion and contraction due to changes in temperature after a certain period of time, causing water leakage problems due to cracks in the base surface and rupture of the waterproof layer. It is a situation in which the problem of increasing the repair cost of the building occurs frequently.

Therefore, in the conventionally disclosed Patent No. 10-0746574, adjacent waterproof sheets are laid horizontally on the construction surface so that their ends do not overlap, but a strip-shaped fiber sheet band is laid on the construction surface where the ends are located, and each waterproof sheet is non-adhesive on top of it. The fiber sheet and the waterproof sheet are installed in this order, and the gap between the waterproof sheets is filled with rubber material in a T shape, and the ends of the waterproof sheets on both sides are covered with fiber sheet bands of the same shape as above, and then nailed to the construction surface. After fixing, the technology of laying a non-adhesive fiber sheet and applying a finishing waterproof paint has been registered in advance.

However, in the prior art, the anti-root function is lost due to the fine unbonding of the joint tape and the construction defect of the welding portion of the joint. The evil followed.

KR 10-0746574 B1 (2007.07.31.)

Accordingly, the present invention has been conceived to solve the above problems, and since the joints are overlapped in the vertical direction between the compound layers of the waterproof anticorrosive sheet to form an overlapping part, the watertightness and durability against external stress are highly improved. In particular, waterproof anticorrosive The purpose is to provide a waterproofing system using a diagonal intaglio pattern that can effectively block the spread of leaks while smoothly distributing and moving wetness while flexibly absorbing the wetting behavior by the diagonal intaglio pattern formed on the bottom of the sheet. .

In order to achieve this object, the feature of the present invention is a waterproofing system using a diagonal intaglio pattern that can be constructed in an exposed or non-exposed manner, and is constructed to finish the concrete surface (1), and has a thickness of 0.5 to 1.2 mm. A waterproof anticorrosive sheet 20 formed by laminating a PVC sheet and reinforcing glass fibers is provided, and the waterproof anticorrosive sheet 20 has an intaglio pattern with a width of 1 to 5 mm to provide a wet behavior absorption and a wet discharge passage on the bottom surface (21) is formed, and the intaglio patterns 21 are formed of lattice-type inclined lines crossing in opposite directions or formed of zigzag lines in the form of brickwork, and the internal pressure is distributed by the intaglio pattern 21. It is provided to prevent swelling, and the waterproof anti-corrosion sheet 20 has a split strip 21a installed at each predetermined section in the longitudinal direction, and the intaglio of the adjacent waterproof anti-corrosion sheet 20 is formed by the split strip 21a. The pattern 21 is disconnected, characterized in that it is provided to block the diffusion of leaks.

At this time, when the waterproof anti-corrosive sheet 20 is constructed in an exposed manner, the porous foam sheet 200 and the aluminum sheet 100 are integrally formed on the bottom of the waterproof anti-corrosive sheet 20, and the aluminum sheet 100 is It is characterized in that it is provided so as to be adhesively applied to the adhesive primer layer 10 formed on the surface 1.

In addition, the waterproof anti-corrosive sheet 20 has one end in the width direction expanded compared to the foam sheet 200 and the aluminum sheet 100 to form a wing portion 23, and the wing portion 23 is adjacent to the waterproof anti-corrosive sheet (20) It is characterized in that it is provided to be finished by the coating layer 27 in a state of overlapping construction on the upper surface.

In addition, the upper surface of the waterproof anti-corrosion sheet 20 is characterized in that it is provided to be finished by the top coating layer 38.

In addition, when the waterproof anti-corrosive sheet 20 is constructed in a non-exposed manner, a self-adhesive compound layer 22 is formed on the bottom of the waterproof anti-corrosive sheet 20, and the waterproof anti-corrosive sheet 20 has a self-adhesive compound layer 22 It is characterized in that the overlapping construction is performed on the upper surface of the neighboring waterproof anti-corrosive sheet 20 together with, and the end of the overlapping area of the waterproof anti-corrosive sheet 20 is provided to be finished by the coating layer 27.

In addition, the self-adhesive compound layer 22 at one end of the waterproof anti-corrosive sheet 20 in the width direction is expanded compared to the width of the waterproof anti-corrosive sheet 20 to form the inner wing portion 22a, and the width of the waterproof anti-corrosive sheet 20 The waterproof root sheet 20 at one end in the other direction is expanded compared to the width of the self-adhesive compound layer 22 to form the outer wing 24, the inner wing 22a is located at the bottom, and the outer wing ( 24) is overlapped with the waterproof anti-corrosive sheet 20 so that it is located on the upper part, and the outer wing portion 24 is spaced apart from the upper surface of the overlapping waterproof anti-corrosive sheet 20 to form a 'c'-shaped space portion 25, , It is characterized in that a part of the coating layer 27 that closes the upper region of the waterproof anti-corrosion sheet 20 is introduced into the 'c'-shaped space portion 25 to form a negative and positive angle binding portion 25a.

In addition, the waterproof root-proof sheet 20 includes a lower sheet 20a, a composite root-proof mesh 20b laminated on the upper surface of the lower sheet 20a and woven with a composite yarn made of metal yarn and synthetic resin yarn, and a composite root-proof mesh 20b ) Above, a plurality of pockets 20c forming partitions along the slope, a metal powder layer 20d filled in the pocket 20c whose lower part is closed by the lower sheet 20a, and a composite mesh ( 20b) It is characterized in that it includes a top sheet 20e stacked on the top surface to close the top of the pocket 20c.

In addition, the heating wire 40 is inserted into the composite mesh 20b of the waterproof anti-rot sheet 20, or the heating wire 40 is provided so as to pass through the pocket 20c in the longitudinal direction of the waterproof anti-root sheet 20 , The heating wire 40 is heated to 50 ~ 70 ℃ by the power module 42, characterized in that provided to wither the plant roots that have penetrated into the waterproof anti-root sheet 20.

In addition, an optical fiber line 50 is inserted into the composite root-proof mesh 20b, or an optical fiber line 50 is provided so as to pass through the pocket 20c in the longitudinal direction of the waterproof root-proof sheet 20, and the optical fiber line 50 Is connected to the LED light source module 52 and is characterized in that it is provided to wither plant roots penetrating into the waterproof root-proof sheet 20 while outputting a light source into the waterproof root-proof sheet 20.

In addition, the overlapping area of the waterproof anti-corrosion sheet 20 is finished by the waterproof anti-corrosion tape 30, the waterproof anti-corrosion tape 30 is formed of a PET layer 32 and an anti-corrosion metal layer 34, and the anti-corrosion metal layer ( 34) is characterized in that it is formed of a copper film or copper mesh.

In addition, the composite anti-corrosion mesh 20b includes a first copper wire 28, and the first copper wire 28 is exposed to both ends of the waterproof anti-corrosion sheet 20 to form a first joint terminal 28a, A second copper wire 38 is included in the anticorrosive metal layer 34 of the anticorrosive tape 30, and the secondary copper wire 38 is exposed to both ends of the anticorrosive tape 30 to form a second joint terminal 38a, The first joint terminal 28 is bent to surround the upper surface of the waterproof root-proof sheet 20, the second joint terminal 38a is bent to surround the lower surface of the waterproof root-proof tape 30, and the first and second joints The terminals 28 and 38 are in contact with each other at the junction of the waterproof anti-corrosive sheet 20 and the waterproof anti-corrosive tape 30 to form a copper band (G).

In addition, by connecting the (+) electrode of the power supply unit (E) to the first copper wire 28, and connecting the (-) electrode of the power supply unit (E) to the second copper wire 38, the waterproof anticorrosive sheet 20 ) And the first and second joint terminals 28 and 38 at the junction boundary of the waterproof tape 30 are characterized in that they are provided to be joined by arc welding.

According to the above configuration and operation, the present invention is highly improved in watertightness and durability against external stress because the joints are overlapped in the vertical direction between the compound layers of the waterproof anticorrosive sheet to form an overlapping portion, and in particular, the sand formed on the bottom of the waterproof anticorrosive sheet Wetting behavior is flexibly absorbed by the linear intaglio pattern, and the diffusion of leaks can be effectively blocked while the wetting is smoothly distributed and moved.

1 is a configuration diagram showing a state in which a waterproof anticorrosive system using an oblique intaglio pattern according to an embodiment of the present invention is constructed in an exposed and non-exposed manner.
Figure 2 is a configuration diagram showing the intaglio pattern of a waterproof root system using an oblique intaglio pattern according to an embodiment of the present invention.
Figure 3 is a configuration diagram showing the internal structure of the waterproof anti-corrosive sheet of the waterproof anti-corrosion system using a diagonal intaglio pattern according to an embodiment of the present invention.
Figure 4 is a configuration diagram showing a heating hot wire and an optical fiber of a waterproof anticorrosive system using a diagonal intaglio pattern according to an embodiment of the present invention.
Figure 5 is a configuration diagram showing the first and second junction terminals of a waterproof root system using a diagonal intaglio pattern according to an embodiment of the present invention.
Figure 6 is a configuration diagram showing a state in which the first and second joint terminals of the waterproof anticorrosive system using a diagonal intaglio pattern according to an embodiment of the present invention are joined.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in the description of the present invention, if it is determined that the related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted.

1 is a configuration diagram showing a state in which a waterproof anticorrosive system using an oblique intaglio pattern according to an embodiment of the present invention is constructed in an exposed and non-exposed manner, and FIG. 2 is an oblique intaglio according to an embodiment of the present invention. It is a configuration diagram showing the intaglio pattern of a waterproof root-proof system using a pattern, and FIG. 3 is a block diagram showing the internal structure of a waterproof root-proof sheet of a waterproof root-proof system using an oblique intaglio pattern according to an embodiment of the present invention. FIG. It is a configuration diagram showing a heating wire and an optical fiber of a waterproof anticorrosive system using an oblique intaglio pattern according to an embodiment of the present invention, and FIG. It is a configuration diagram showing 1 and 2 junction terminals, and FIG. 6 is a configuration diagram showing a state in which the first and second junction terminals of a waterproof anticorrosive system using a diagonal intaglio pattern according to an embodiment of the present invention are joined.

The present invention relates to a waterproof anticorrosive system using an oblique intaglio pattern constructed in an exposed or non-exposed manner, and since the joints between the compound layers of the waterproof anticorrosive sheet are overlapped in the vertical direction to form an overlapping portion, watertightness and durability against external stress In particular, the wetting behavior is flexibly absorbed by the oblique intaglio pattern formed on the bottom of the waterproof anticorrosive sheet, and the PVC sheet and the reinforcing glass fiber are laminated to effectively block the diffusion of water leakage while smoothly distributing and moving the wetness. It is the main configuration, including the waterproof anticorrosive sheet 20 formed by the.

The waterproof root guard system using the oblique intaglio pattern according to the present invention is constructed to finish the concrete base surface (1), and is formed by laminating a PVC sheet having a thickness of 0.5 to 1.2 mm and reinforcing glass fibers (20) is provided

In FIG. 2, the waterproof anticorrosive sheet 20 has an intaglio pattern 21 having a width of 1 to 5 mm for absorbing wet behavior and providing a wet discharge passage on the bottom surface.

At this time, the intaglio patterns 21 are formed of lattice-like inclined lines crossing each other in opposite directions, or are formed of zigzag lines in the form of brickwork.

As such, the waterproof anti-corrosion sheet 20 absorbs the wet behavior flexibly due to the intaglio pattern 21 and smoothly disperses and moves the moisture, and in particular, the waterproof anti-corrosion sheet 20 swells due to the dispersion of the internal pressure including the water vapor pressure rise is prevented.

In the waterproof anti-root sheet 20, a dividing strip 21a is installed at each predetermined section in the longitudinal direction, and the intaglio pattern 21 of the neighboring waterproof anti-root sheet 20 is cut off by the dividing strip 21a, thereby preventing water leakage. spread can be effectively prevented. At this time, the dividing band 21a is formed of a waterproof member including a water-stop material and a water-tight packing.

Figure 1 (a) is a configuration diagram showing a state in which the waterproof anticorrosive system using an oblique intaglio pattern according to the present invention is constructed in an exposed manner.

In addition, when the waterproof anticorrosion sheet 20 is constructed in an exposed manner, the porous foam sheet 200 and the aluminum sheet 100 are integrally formed on the bottom surface of the waterproof anticorrosive sheet 20. Heat insulation is added to the waterproof anticorrosive sheet 20 by the foam sheet 200 and the aluminum sheet 100.

Here, the foam sheet 200 is an intermediate layer connecting the base surface 1 and the waterproof anti-rot sheet 20 to be described later, and the foam sheet 200 flattens the base surface 1 to form a waterproof anti-rot sheet 20 In addition to the improved workability, wetting movement is performed quickly due to the fine pores.

At this time, the aluminum sheet 100 is provided to be bonded to the adhesive primer layer 10 formed on the base surface 1.

In addition, one end of the waterproof anti-corrosion sheet 20 in the width direction is expanded compared to the foam sheet 200 and the aluminum sheet 100 to form a wing portion 23, and the wing portion 23 is adjacent to the waterproof anti-corrosion sheet. (20) It is provided to be finished by the coating layer 27 in a state of overlapping construction on the upper surface.

In addition, the upper surface of the waterproof anti-corrosion sheet 20 is provided to be finished with a top coating layer 38. Here, the top coating layer 38 is formed of a urethane coating and is provided to protect the upper portion of the waterproof anticorrosive sheet 20.

Figure 1 (b) is a configuration diagram showing a state in which the waterproof anticorrosive system using a diagonal intaglio pattern according to the present invention is constructed in a non-exposure manner.

When the waterproof anti-corrosive sheet 20 is constructed in a non-exposed manner, a self-adhesive compound layer 22 is formed on the bottom of the waterproof anti-corrosive sheet 20, and the waterproof anti-corrosive sheet 20 is combined with the self-adhesive compound layer 22 It is overlapped on the upper surface of the neighboring waterproof anticorrosive sheet 20.

At this time, the end of the overlapping region of the waterproof anticorrosive sheet 20 is provided to be closed by the coating layer 27.

The self-adhesive compound layer 22 at one end of the waterproof root-proof sheet 20 in the width direction is expanded compared to the width of the waterproof root-proof sheet 20 to form an inner wing portion 22a, and the other waterproof root-proof sheet 20 in the width direction The waterproof anti-corrosion sheet 20 at one end is expanded compared to the width of the self-adhesive compound layer 22 to form the outer wing portion 24.

The inner wing portion 22a is located at the bottom, and the outer wing portion 24 is overlapped with the waterproof anticorrosive sheet 20 so that it is located at the top.

In this way, when the waterproof anti-corrosive sheet 20 is overlapped, the inner wing portion 22a is adhered to the self-adhesive compound layer 22 of the neighboring waterproof anti-corrosive sheet 20, that is, the self-adhesive compound layer of the same material ( 22) has the advantage of highly improving watertightness and durability against external stress by overlapping with each other.

At this time, the outer wing portion 24 is spaced apart from the upper surface of the overlapping waterproof anti-rot sheet 20 to form a 'c'-shaped space portion 25. The 'c'-shaped space portion 25 is formed to a depth of 5 to 10 mm.

In addition, as a part of the coating layer 27 that closes the upper area of the waterproof anti-corrosive sheet 20 flows into the 'c'-shaped space 25 and is provided to form a negative and embossed binding portion 25a, the waterproof anti-corrosive sheet 20 ), there is an advantage in that the lifting phenomenon is prevented in the overlapping area and the waterproof stability is highly improved.

In FIG. 3, the waterproof root-proof sheet 20 includes a lower sheet 20a, a composite root-proof mesh 20b laminated on the upper surface of the lower sheet 20a and woven with a composite yarn composed of metal yarn and synthetic resin yarn, and a composite root-proof mesh On top of (20b), a plurality of pockets 20c forming partitions with an inclination as a boundary, a metal powder layer 20d filled in the pocket 20c whose lower part is closed by the lower sheet 20a, and a composite method A top sheet 20e is stacked on the upper surface of the mesh 20b to close the upper portion of the pocket 20c.

At this time, the metal yarn and metal powder layer 20d included in the composite root-proof mesh 20b have a root-proof function for plant roots into the waterproof root-proof sheet 20, and also waterproof by the composite root-proof mesh 20b. The durability of the anticorrosive sheet 20 is improved, and the manufacturing cost of the anticorrosive sheet 20 is reduced by selectively applying powder containing various metal components including copper powder, iron powder, and blast furnace sludge to the inside of the pocket 20c. There is an advantage to being

In FIG. 4 (a), a heating wire 40 containing carbon fiber is inserted into the composite mesh 20b of the waterproof anti-corrosion sheet 20, or a pocket 20c is provided in the longitudinal direction of the waterproof anti-corrosion sheet 20 A heating hot wire 40 including carbon fiber is provided to pass through.

In addition, the heating wire 40 is heated to 50 to 70 ° C by the power module 42 to wither the plant roots penetrating into the waterproof anti-rot sheet 20, and also heats the waterproof anti-rot sheet 20 in winter. Therefore, damage such as cracking is prevented in advance by being flexibly deformed in response to the expansion and contraction behavior of the concrete base surface 1 due to the temperature difference.

In FIG. 4 (b), the optical fiber line 50 is inserted into the composite mesh 20b of the waterproof anti-corrosive sheet 20, or the optical fiber line passes through the pocket 20c in the longitudinal direction of the waterproof anti-corrosive sheet 20 ( 50) is provided.

In addition, the optical fiber line 50 is connected to the LED light source module 52 and outputs a light source into the waterproof anti-rot sheet 20 and is provided to wither plant roots penetrating into the waterproof anti-rot sheet 20. At this time, the LED light source module 52 is provided to output a light source of a wavelength band having excellent plant root death efficiency.

In Figure 5, the overlapping area of the waterproof anti-corrosion sheet 20 is closed by the waterproof anti-corrosion tape 30.

The waterproof anticorrosive tape 30 is formed of a PET layer 32 and an anticorrosive metal layer 34, and the anticorrosive metal layer 34 is formed of a copper film or copper mesh.

In addition, the composite anti-corrosion mesh 20b includes a first copper wire 28, and the first copper wire 28 is exposed to both ends of the waterproof anti-corrosion sheet 20 to form a first joint terminal 28a, A second copper wire 38 is included in the anticorrosive metal layer 34 of the anticorrosive tape 30, and the secondary copper wire 38 is exposed to both ends of the anticorrosive tape 30 to form a second joint terminal 38a.

In addition, the first joint terminal 28 is bent to surround the upper surface of the waterproof anticorrosive sheet 20, and the second joint terminal 38a is bent to surround the lower surface of the waterproof anticorrosive tape 30, and the first, The two junction terminals 28 and 38 are provided to form a copper band G by being in contact with each other at the junction of the waterproof anti-corrosive sheet 20 and the waterproof anti-corrosive tape 30.

In this way, as the copper band (G) is formed at the junction of the waterproof anti-root sheet 20 and the waterproof anti-root tape 30, penetration of plant roots is effectively blocked.

In FIG. 6, by connecting the (+) electrode of the power supply unit (E) to the first copper wire 28 and connecting the (-) electrode of the power supply unit (E) to the second copper wire 38, the waterproof anticorrosive sheet (20) and the waterproof tape 30 at the junction boundary, the first and second joint terminals 28, 38 are provided to be joined by arc welding.

As the first and second joint terminals 28 and 38 are melted and joined by arc welding, the joint boundary between the waterproof anti-corrosive sheet 20 and the waterproof anti-corrosive tape 30 is closed with copper wire, so that the structural bonding strength of the joint increases. In addition to being improved, penetration of plant roots between the waterproof root-proof sheet 20 and the waterproof root-proof tape 30 is closely blocked.

As described above, the most preferred embodiment of the present invention has been described in the detailed description of the present invention, but various modifications may be made within a range that does not depart from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

10: adhesive primer layer 20: anticorrosive waterproof sheet
30: anticorrosive tape 40: heating wire
50: fiber optic line
100: aluminum sheet 200: foam sheet

Claims (12)

In the waterproofing system using an oblique intaglio pattern that can be constructed in an exposed or non-exposed manner,
It is constructed to finish the concrete base surface (1), and is provided with a waterproof anticorrosive sheet 20 formed by laminating a PVC sheet having a thickness of 0.5 to 1.2 mm and reinforcing glass fibers,
The waterproof anti-corrosion sheet 20 has an intaglio pattern 21 having a width of 1 to 5 mm to provide a wet behavior absorption and a wet discharge passage on the bottom surface,
The intaglio patterns 21 are formed of lattice-like inclined lines crossing in opposite directions or are formed of zigzag lines in the form of brickwork, and are provided to prevent swelling due to internal pressure dispersion by the intaglio patterns 21 becomes,
In the waterproof anti-root sheet 20, a dividing strip 21a is installed at each predetermined section in the longitudinal direction, and the intaglio pattern 21 of the neighboring waterproof anti-root sheet 20 is cut off by the dividing strip 21a, thereby preventing water leakage. Equipped to block diffusion,
The waterproof root-proof sheet 20 includes a lower sheet 20a, a composite root-proof mesh 20b laminated on the upper surface of the lower sheet 20a and woven with a composite yarn made of metal yarn and synthetic resin yarn, and a composite root-proof mesh 20b. Above, a plurality of pockets 20c forming partitions with an inclination boundary, a metal powder layer 20d filled in the pocket 20c whose lower part is closed by the lower sheet 20a, and a composite mesh 20b A waterproof root system using an oblique intaglio pattern, characterized in that it comprises an upper sheet (20e) that is laminated on the upper surface and closes the upper portion of the pocket (20c).
According to claim 1,
When constructing the waterproof anticorrosive sheet 20 in an exposed manner,
The porous foam sheet 200 and the aluminum sheet 100 are integrally formed on the bottom of the waterproof anti-corrosion sheet 20,
The aluminum sheet 100 is a waterproof anticorrosive system using a diagonal intaglio pattern, characterized in that provided to be bonded to the adhesive primer layer 10 formed on the base surface (1).
According to claim 2,
The waterproof anti-corrosive sheet 20 has one end in the width direction extended relative to the foam sheet 200 and the aluminum sheet 100 to form a wing portion 23, and the wing portion 23 is adjacent to the waterproof anti-corrosive sheet 20 ) Waterproof anticorrosive system using an oblique intaglio pattern, characterized in that it is provided to be finished by the coating layer 27 in a state of overlapping construction on the upper surface.
According to claim 3,
The waterproof anti-corrosion system using a diagonal intaglio pattern, characterized in that the upper surface of the waterproof anti-corrosion sheet 20 is provided to be finished by the top coating layer 38.
According to claim 1,
When constructing the waterproof anticorrosive sheet 20 in a non-exposure manner,
A self-adhesive compound layer 22 is formed on the bottom of the waterproof anti-corrosion sheet 20,
The waterproof anticorrosive sheet 20 is overlapped on the upper surface of the neighboring waterproof anticorrosive sheet 20 together with the self-adhesive compound layer 22,
The waterproof anti-corrosion system using an oblique intaglio pattern, characterized in that the end of the overlapping area of the waterproof anti-corrosion sheet 20 is provided to be finished by the coating layer 27.
According to claim 5,
The self-adhesive compound layer 22 at one end of the waterproof anti-corrosion sheet 20 in the width direction is expanded compared to the width of the waterproof anti-corrosive sheet 20 to form an inner wing 22a, and the waterproof anti-corrosion sheet 20 in the width direction The waterproof anti-corrosive sheet 20 at one end is expanded compared to the width of the self-adhesive compound layer 22 to form an outer wing 24,
The inner wing portion 22a is located at the bottom, and the outer wing portion 24 is overlapped with the waterproof anticorrosive sheet 20 so that the outer wing portion 24 is located at the top,
The outer wing portion 24 is spaced apart from the upper surface of the overlapping waterproof anti-rot sheet 20 to form a 'c'-shaped space portion 25,
Diagonal intaglio, characterized in that a part of the coating layer 27 finishing the upper region of the waterproof anti-corrosion sheet 20 flows into the 'c'-shaped space 25 to form an embossed binding portion 25a Waterproofing system using patterns.
delete According to claim 1,
The heating wire 40 is inserted into the composite mesh 20b of the waterproof anti-rot sheet 20, or the heating wire 40 is provided so as to pass through the pocket 20c in the longitudinal direction of the waterproof anti-rot sheet 20, The heating wire 40 is heated to 50 ~ 70 ° C by the power module 42 and is provided to wither plant roots that have penetrated into the waterproof rooting sheet 20. system.
According to claim 1,
An optical fiber line 50 is inserted into the composite root-proof mesh 20b, or an optical fiber line 50 is provided so as to pass through the pocket 20c in the longitudinal direction of the waterproof root-proof sheet 20, and the optical fiber line 50 is an LED. It is connected to the light source module 52 and outputs a light source to the inside of the waterproof anti-rot sheet 20, characterized in that it is provided to withhold plant roots that have penetrated into the waterproof anti-root sheet 20. system.
According to claim 1 or 5,
The overlapping area of the waterproof anti-corrosive sheet 20 is finished by the waterproof anti-corrosion tape 30, and the waterproof anti-corrosion tape 30 is formed of a PET layer 32 and an anti-corrosion metal layer 34, and the anti-corrosion metal layer 34 A waterproof anticorrosive system using a diagonal intaglio pattern, characterized in that it is formed of a silver copper film or copper mesh.
According to claim 10,
A first copper wire 28 is included in the composite anticorrosive mesh 20b, and the first copper wire 28 is exposed to both ends of the waterproof anticorrosive sheet 20 to form a first joint terminal 28a,
A second copper wire 38 is included in the anticorrosive metal layer 34 of the waterproof anticorrosive tape 30, and the second copper wire 38 is exposed to both ends of the waterproof anticorrosive tape 30 to form a second joint terminal 38a and
The first joint terminal 28 is bent to surround the upper surface of the waterproof anti-corrosive sheet 20, and the second joint terminal 38a is bent to surround the lower surface of the waterproof anti-corrosive tape 30,
The first and second junction terminals 28 and 38 are in contact with each other at the junction of the waterproof anti-corrosive sheet 20 and the waterproof anti-corrosive tape 30 to form a copper band (G) Diagonal intaglio, characterized in that provided Waterproofing system using patterns.
According to claim 11,
The (+) electrode of the power supply unit (E) is connected to the first copper wire (28), and the (-) electrode of the power supply unit (E) is connected to the second copper wire (38) to form a waterproof anticorrosive sheet (20) and Waterproof anticorrosive system using an oblique intaglio pattern, characterized in that the first and second joint terminals 28 and 38 are provided to be joined by arc welding at the junction boundary of the waterproof anticorrosive tape 30.

Images